Full-length myotonin protein kinase (72 kDa) displays serine kinase activity.

We describe the full-length (72 kDa) myotonin protein kinase (Mt-PK) and demonstrate its kinase activity. The 72-kDa protein corresponds to the translation product from the first in-frame AUG codon. This protein was found in the cytoplasmic fraction, whereas the previously reported 55-kDa protein was observed in nuclear extracts. Only the 72-kDa protein was phosphorylated by [32P]phosphate in normal human fibroblasts. To investigate the putative kinase activity of Mt-PK, a construct containing the full-length open reading frame of Mt-PK was expressed in bacterial cells. The recombinant Mt-PK autophosphorylates a Ser residue and phosphorylates the synthetic peptide Gly-Arg-Gly-Leu-Ser-Leu-Ser-Arg, which contains a Ser residue in the phosphorylation site. We examined phosphorylation of the voltage-dependent Ca(2+)-release channel, or dihydropyridine receptor (DHPR), by recombinant Mt-PK. We observed that the beta subunit of DHPR was phosphorylated in vitro by Mt-PK. A beta-subunit DHPR peptide containing some of the Ser residues predicted to be phosphorylated was synthesized and found to be a substrate for Mt-PK in vitro. We conclude that the 72-kDa Mt-PK has a protein kinase activity specific for Ser residues.

Developmental and tissue-specific regulation of mouse telomerase and telomere length.

Telomere shortening and telomerase activation in human somatic cells have been implicated in cell immortalization and cellular senescence. To further study the role of telomerase in immortalization, we assayed telomere length and telomerase activity in primary mouse fibroblasts, in spontaneously immortalized cell clones, and in mouse tissues. In the primary cell cultures, telomere length decreased with increased cell doublings and telomerase activity was not detected. In contrast, in spontaneously immortalized clones, telomeres were maintained at a stable length and telomerase activity was present. To determine if telomere shortening occurs in vivo, we assayed for telomerase and telomere length in tissues from mice of different ages. Telomere length was similar among different tissues within a newborn mouse, whereas telomere length differed between tissues in an adult mouse. These findings suggest that there is tissue-specific regulation of mouse telomerase during development and aging in vivo. In contrast to human tissues, most mouse tissues had active telomerase. The presence of telomerase in these tissues may reflect the ease of immortalization of primary mouse cells relative to human cells in culture.